Hand rubbing nuclear fusion live in the wilderness

Chapter 516 The Discovery of the Collision Experiment

The collision experiment at the 30Tev energy level has brought countless data and information to the Korean Won.

The hydrogen particles rushing through the particle acceleration pipeline at close to the speed of light, every collision is as rare as a feather.

But every time it collides, like the sparks of a prairie fire, it brings hope.

The various detectors deployed on the acceleration orbit, such as the super toroidal instrument, the compact muon coil, the quark particle detector, and the cross-sectional elastic scattering detector, have captured various data generated during the collision of hydrogen particles.

After being sorted by the central computer, these data evolved into a pair of energy spectrum images, which were then displayed in front of his eyes.

Looking at the data and energy spectrum on the display screen, Han Yuan showed a bright smile on his face.

The successful operation of the Large Intense Particle Collider represents a new future for the physics community.

Although the energy level of the zero particle collider in the simulated space is only one more zero than that of the LHC.

But this means that various particles and data that have never been discovered before will unveil their mysteries.

The buildings in the physics world will be built higher and bigger, and even another one will be erected, soaring into the sky.

The first power-on trial run experiment ended perfectly with the 30Tev energy level collision experiment. After collecting all kinds of data, the X-1 industrial robot began to inspect and maintain the underground large-scale strong particle collision under the arrangement of Xiao Ling. machine.

And Han Yuan returned to the workplace again, and began to concentrate on analyzing various collected data.

The 30Tev energy level collision experiment has surpassed the highest energy level collision experiment that humans have ever conducted in reality.

Under the impetus of this energy level, no one knows what kind of elementary particles will be produced by the collision between hydrogen particles.

This is pioneering work, and the data contained within it may or may not hold promise.

In the studio, a pair of energy spectrum images and corresponding data tables kept flashing across Han Yuan's eyes.

Although his mathematical knowledge is not as good as physics, and in some cutting-edge fields, he is not as good as those mathematicians standing on the pyramid.

But it is not difficult for him to understand the collision data of the particle collider.

In particular, these data have also been processed by the small zero and the central computer, from raw data to graphics and tables.

The 30Tev energy level particle collision experiment is probably the most expensive pyrotechnics in human history.

But the data it generates, like a piece of green brick, paves the way for human beings to move forward physically.

A pair of energy spectrum images kept flashing before Han Yuan's eyes, and those data with obvious fluctuations and abnormalities were divided into another folder and handed over to the central computer for further processing.

It took five full days for Han Yuan to go through the various data generated by the first power-on trial run experiment.

This is still assisted by Xiaoling, a central computer with artificial intelligence and super computing power.

Of course, the harvest this time is not small.

High-energy particle collision experiments have always been the most important means and ways for human beings to understand the particle world and reveal the interaction rules and structural relationships between the elementary particles that make up matter.

In this 30Tev energy level particle collision experiment, Han Yuan found the β boson in the standard model Higgs particle of the H→WW*→lvlv decay path produced in the high-energy inelastic collision in the collected detection data child particles.

The Higgs particle is a term in physics. In a broad sense, all particles that appear in the Higgs mechanism can be called Higgs ions.

But he is usually used to refer to the Higgs particle in the Standard Model.

And the β boson particle in the Higgs particle is a kind of standard particle predicted by the Higgs mechanism, and it explains the mechanism of the mass origin of the elementary particle.

But so far nothing has been confirmed.

If there is a particle collision experiment that can discover the Higgs particle β boson particle, it will confirm the Higgs mechanism and make the Standard Model a relatively perfect theory.

The reason why the Higgs particle β boson particles cannot be observed so far is that they will rapidly decay and disappear at the moment of birth, and their existence cannot be directly observed.

Physicists can study Higgs bosons indirectly, though, based on the products they leave behind after they decay.

But it is very difficult to be 100% sure that what we found is the trace left by the Higgs boson.

Therefore, current physical scientists have only found signs of the existence of the Higgs boson, and cannot 100% confirm that this boson does exist.

In the simulated space, Han Yuan found the Higgs particle β Bose through various detectors deployed on the acceleration orbit, such as the super torus instrument, the compact muon coil, the quark particle detector, and the cross-sectional elastic scattering detector. existence of child.

Although this existence is very short, the peak that appears is also very weak.

But through data analysis, he still confirmed the existence of the Higgs particle beta boson particle.

Won is very interested in the discovery of the Higgs beta boson.

Its discovery can be said to perfectly demonstrate the correctness of the "Higgs mechanism" of the mass origin mechanism of elementary particles, and further maintain the standard model, making the standard model a relatively perfect theory.

The relatively perfect standard model can explain the composition of dark physics and explain whether the current elementary particles are composed of more elementary particles.

As well as unifying 'gravity' into the framework of the Standard Model as well.

This is the most important discovery in this 30Tev energy level particle collision experiment.

Although for Won, what he hoped to find did not appear in this 30Tev energy level particle collision experiment, the importance of the discovery of the Higgs particle β boson is also self-evident.

And he also knows that it is an unrealistic fantasy to find supergravitons through a single collision experiment.

The particle collision of 30Tev energy level cannot be found, just continue to increase the energy level and continue to do it.

If hypergraviton, a high-energy particle that can induce gravity and cause space to expand, is found in a 30Tev energy level collision experiment, Han Yuan will doubt his life instead.

The discovery of the Higgs particle β boson, its integration into the existing standard model of physics, and the study of this standard particle have very important physical significance.

Firstly, the fusion process of the Higgs particle β boson can not only be used to directly test the "electroweak violation mechanism" of the standard model.

In the Standard Model, in the absence of the Higgs particle, the scattering amplitude of a longitudinally polarized W or Z boson increases without limit with energy until unitarity violation occurs at TeV energies .

In addition to perfecting the Standard Model, the Higgs beta boson has a larger purpose.

That is explaining the origin of matter!
That's right, the Higgs particle beta boson particle can explain how the universe created matter, and it can also explain how a part of the singularity big bang formed the universe.

Of course, this is only the current view of human scientists.

After all, the various basic knowledge and information of mathematics and physics that Han Won has learned are sorted out by this system from human science and technology theories.

And in today's physics world.Scientists think of the Higgs beta boson as the particle that gives other particles their mass.

It is because the Higgs boson gives other particles their mass that particles can combine together to form all kinds of matter.

The Higgs boson is therefore known as the "God particle" that shaped the entire universe.

When mentioning the Higgs particle or the Higgs particle β boson, the Higgs field must be mentioned.

The Higgs field is a quantum field assumed to exist throughout the universe, and the Higgs particle is produced by Higgs field vibrations.

If the Higgs beta can be found, it can be assumed that the Higgs field is indeed pervasive throughout the universe.

The discovery of the Higgs particle and the Higgs particle β boson can prove the existence of the Higgs field from the side, and then prove that the Higgs mechanism and the standard model are also correct.

If the discovery of the Higgs particle and the Higgs particle beta boson is just to demonstrate the existence of the Higgs field and prove that the Standard Model is correct, Won would not be so interested.

What he is interested in is that the Higgs field can produce Higgs particles through vibration.

In the theory of physicist Higgs, if there is no Higgs field, then there will be no visible matter in the universe today.

Because when electrons have no mass, atoms are bigger.

This will cause atoms to collide with each other and cannot exist alone, and various visible substances cannot be born, and the universe may be a chaotic nothingness.

So the existence of the Higgs field is the machine that the universe produces various substances.

Of course, the Higgs field will also change in particularly extreme environments, such as when the temperature is extremely high or reaches absolute zero, the Higgs field cannot remain stable.

But it is almost impossible to achieve such a temperature.

In order to make the Higgs field unable to maintain stability through high temperature, only the universe can reach such a high temperature immediately after the big bang.

And in the extreme low temperature environment, which is the so-called "absolute zero", the Higgs field will also become unstable, and will be reduced to the lowest energy state, forming the absolute vacuum in quantum mechanics.

But in essence, it is theoretically impossible for the universe to enter absolute zero, and at the same time, there will still be a certain amount of background energy in the universe when entering absolute zero.

Extremely high temperature and extremely low temperature are impossible to achieve from the current theory.

So the Higgs field, if it exists, is almost 100% stable.

After all, if the Higgs field is unstable, our physical world will be messed up.

Now that the Higgs particle β boson has been found, the Higgs field can also pass the theoretical demonstration.

If it is possible to find out exactly how the Higgs field creates the Higgs particle and the Higgs beta boson through the Large Intense Particle Collider, it would be great for Won.

Meaning he could find a way to convert energy into matter.

In other words, find a way to create the Higgs particle and the Higgs beta boson out of thin air.

For human beings, this can be said to be a real forbidden zone for God.

Although there are some special particles in the universe that do not interact with the Higgs field.

'Photons' and 'gluons' are good examples.

The mass of a static photon is zero, while the moving photon will generate kinetic energy to produce a certain amount of energy. In essence, energy and mass are equivalent.

But do you care when you can make most of the matter through Higgs field oscillations?
Suddenly, Han Yuan remembered a novel he had read a long time ago.

In that science fiction novel, there is a civilization that can create various substances out of thin air, and then transform the substances into various equipment or materials they need.

At the time, this kind of setting seemed to everyone to regard it as a joke.

But in his eyes now, it doesn't seem unfeasible.

As long as he can control the Higgs field, and control its vibrations.

The appearance of the Higgs particle β boson is the most important thing for the physics community.

The standard model has been completely completed, and the strong interaction, weak interaction, and electromagnetic interaction have been unified, and a new chapter has been opened in the field of physics.

For the Korean won, its presence is just as important.

The vibration of the Higgs field can create Higgs particles out of thin air, which involves the origin of the universe and matter, and he will not let go of this research opportunity.

But researching it is for later.

The most important thing now is to continue to restart the particle collision experiment and find the supergraviton suitable for the faster-than-light flight technology.

After the first 30Tev energy level collision experiment was completed, half a month later, the large-scale strong particle collider built underground finally completed the inspection and maintenance work, and the collision experiment can be started again.

This time, Won did not start the 35Tev energy level collision experiment as originally planned.

Instead, the energy level of the collision experiment was adjusted to 50Tev.

This adjustment was not made on a whim, but was made with reference to some data from the last 30Tev energy level particle collision experiment.

Compared with the 50Tev energy level collision experiment, the 30Tev energy level collision experiment has only 20Tev energy levels more, but the power consumption has more than doubled.

After ten days of preparation, the second high-energy particle collision experiment was launched again.

The huge energy output from the controllable nuclear fusion is like a raging flood, gathered in the superconducting magnetic rings on the narrow and long acceleration pipeline of the particle collider, and these superconducting magnetic rings are brewing an explosion comparable to the core of the earth. Scary magnetic field.

Under the shroud of this huge magnetic field, even the cosmic rays that wantonly shuttle around are distorted, not to mention the particles running wild in the particle accelerator pipeline.

They are destined to travel in a tube, never to break free, until they finally come together and break up into elementary particles smaller than atoms.

Quarks, top quarks, down quarks, leptons, and intermediate bosons, which are invisible to the naked eye, show various brilliance on the energy spectrum of the detector, drawing a series of undulating curves.

(End of this chapter)